/* * crypto.h - public data structures and prototypes for the crypto library * * The contents of this file are subject to the Mozilla Public * License Version 1.1 (the "License"); you may not use this file * except in compliance with the License. You may obtain a copy of * the License at http://www.mozilla.org/MPL/ * * Software distributed under the License is distributed on an "AS * IS" basis, WITHOUT WARRANTY OF ANY KIND, either express or * implied. See the License for the specific language governing * rights and limitations under the License. * * The Original Code is the Netscape security libraries. * * The Initial Developer of the Original Code is Netscape * Communications Corporation. Portions created by Netscape are * Copyright (C) 1994-2000 Netscape Communications Corporation. All * Rights Reserved. * * Portions created by Sun Microsystems, Inc. are Copyright (C) 2003 * Sun Microsystems, Inc. All Rights Reserved. * * Contributor(s): * Dr Vipul Gupta , Sun Microsystems Laboratories * * Alternatively, the contents of this file may be used under the * terms of the GNU General Public License Version 2 or later (the * "GPL"), in which case the provisions of the GPL are applicable * instead of those above. If you wish to allow use of your * version of this file only under the terms of the GPL and not to * allow others to use your version of this file under the MPL, * indicate your decision by deleting the provisions above and * replace them with the notice and other provisions required by * the GPL. If you do not delete the provisions above, a recipient * may use your version of this file under either the MPL or the * GPL. * * $Id: blapi.h,v 1.16 2003/05/30 23:31:18 wtc%netscape.com Exp $ */ #ifndef _BLAPI_H_ #define _BLAPI_H_ #include "blapit.h" SEC_BEGIN_PROTOS /* ** RSA encryption/decryption. When encrypting/decrypting the output ** buffer must be at least the size of the public key modulus. */ /* ** Generate and return a new RSA public and private key. ** Both keys are encoded in a single RSAPrivateKey structure. ** "cx" is the random number generator context ** "keySizeInBits" is the size of the key to be generated, in bits. ** 512, 1024, etc. ** "publicExponent" when not NULL is a pointer to some data that ** represents the public exponent to use. The data is a byte ** encoded integer, in "big endian" order. */ extern RSAPrivateKey *RSA_NewKey(int keySizeInBits, SECItem * publicExponent); /* ** Perform a raw public-key operation ** Length of input and output buffers are equal to key's modulus len. */ extern SECStatus RSA_PublicKeyOp(RSAPublicKey * key, unsigned char * output, const unsigned char * input); /* ** Perform a raw private-key operation ** Length of input and output buffers are equal to key's modulus len. */ extern SECStatus RSA_PrivateKeyOp(RSAPrivateKey * key, unsigned char * output, const unsigned char * input); /* ** Perform a raw private-key operation, and check the parameters used in ** the operation for validity by performing a test operation first. ** Length of input and output buffers are equal to key's modulus len. */ extern SECStatus RSA_PrivateKeyOpDoubleChecked(RSAPrivateKey * key, unsigned char * output, const unsigned char * input); /* ** Perform a check of private key parameters for consistency. */ extern SECStatus RSA_PrivateKeyCheck(RSAPrivateKey *key); /******************************************************************** ** DSA signing algorithm */ /* ** Generate and return a new DSA public and private key pair, ** both of which are encoded into a single DSAPrivateKey struct. ** "params" is a pointer to the PQG parameters for the domain ** Uses a random seed. */ extern SECStatus DSA_NewKey(const PQGParams * params, DSAPrivateKey ** privKey); /* signature is caller-supplied buffer of at least 20 bytes. ** On input, signature->len == size of buffer to hold signature. ** digest->len == size of digest. ** On output, signature->len == size of signature in buffer. ** Uses a random seed. */ extern SECStatus DSA_SignDigest(DSAPrivateKey * key, SECItem * signature, const SECItem * digest); /* signature is caller-supplied buffer of at least 20 bytes. ** On input, signature->len == size of buffer to hold signature. ** digest->len == size of digest. */ extern SECStatus DSA_VerifyDigest(DSAPublicKey * key, const SECItem * signature, const SECItem * digest); /* For FIPS compliance testing. Seed must be exactly 20 bytes long */ extern SECStatus DSA_NewKeyFromSeed(const PQGParams *params, const unsigned char * seed, DSAPrivateKey **privKey); /* For FIPS compliance testing. Seed must be exactly 20 bytes. */ extern SECStatus DSA_SignDigestWithSeed(DSAPrivateKey * key, SECItem * signature, const SECItem * digest, const unsigned char * seed); /****************************************************** ** Diffie Helman key exchange algorithm */ /* Generates parameters for Diffie-Helman key generation. ** primeLen is the length in bytes of prime P to be generated. */ extern SECStatus DH_GenParam(int primeLen, DHParams ** params); /* Generates a public and private key, both of which are encoded in a single ** DHPrivateKey struct. Params is input, privKey are output. ** This is Phase 1 of Diffie Hellman. */ extern SECStatus DH_NewKey(DHParams * params, DHPrivateKey ** privKey); /* ** DH_Derive does the Diffie-Hellman phase 2 calculation, using the ** other party's publicValue, and the prime and our privateValue. ** maxOutBytes is the requested length of the generated secret in bytes. ** A zero value means produce a value of any length up to the size of ** the prime. If successful, derivedSecret->data is set ** to the address of the newly allocated buffer containing the derived ** secret, and derivedSecret->len is the size of the secret produced. ** The size of the secret produced will never be larger than the length ** of the prime, and it may be smaller than maxOutBytes. ** It is the caller's responsibility to free the allocated buffer ** containing the derived secret. */ extern SECStatus DH_Derive(SECItem * publicValue, SECItem * prime, SECItem * privateValue, SECItem * derivedSecret, unsigned int maxOutBytes); /* ** KEA_CalcKey returns octet string with the private key for a dual ** Diffie-Helman key generation as specified for government key exchange. */ extern SECStatus KEA_Derive(SECItem *prime, SECItem *public1, SECItem *public2, SECItem *private1, SECItem *private2, SECItem *derivedSecret); /* * verify that a KEA or DSA public key is a valid key for this prime and * subprime domain. */ extern PRBool KEA_Verify(SECItem *Y, SECItem *prime, SECItem *subPrime); /****************************************************** ** Elliptic Curve algorithms */ /* Generates a public and private key, both of which are encoded ** in a single ECPrivateKey struct. Params is input, privKey are ** output. */ extern SECStatus EC_NewKey(ECParams * params, ECPrivateKey ** privKey); extern SECStatus EC_NewKeyFromSeed(ECParams * params, ECPrivateKey ** privKey, const unsigned char* seed, int seedlen); /* Validates an EC public key as described in Section 5.2.2 of * X9.63. Such validation prevents against small subgroup attacks * when the ECDH primitive is used with the cofactor. */ extern SECStatus EC_ValidatePublicKey(ECParams * params, SECItem * publicValue); /* ** ECDH_Derive performs a scalar point multiplication of a point ** representing a (peer's) public key and a large integer representing ** a private key (its own). Both keys must use the same elliptic curve ** parameters. If the withCofactor parameter is true, the ** multiplication also uses the cofactor associated with the curve ** parameters. The output of this scheme is the x-coordinate of the ** resulting point. If successful, derivedSecret->data is set to the ** address of the newly allocated buffer containing the derived ** secret, and derivedSecret->len is the size of the secret ** produced. It is the caller's responsibility to free the allocated ** buffer containing the derived secret. */ extern SECStatus ECDH_Derive(SECItem * publicValue, ECParams * params, SECItem * privateValue, PRBool withCofactor, SECItem * derivedSecret); /* On input, signature->len == size of buffer to hold signature. ** digest->len == size of digest. ** On output, signature->len == size of signature in buffer. ** Uses a random seed. */ extern SECStatus ECDSA_SignDigest(ECPrivateKey *key, SECItem *signature, const SECItem *digest); /* On input, signature->len == size of buffer to hold signature. ** digest->len == size of digest. */ extern SECStatus ECDSA_VerifyDigest(ECPublicKey *key, const SECItem *signature, const SECItem *digest); /* Uses the provided seed. */ extern SECStatus ECDSA_SignDigestWithSeed(ECPrivateKey *key, SECItem *signature, const SECItem *digest, const unsigned char *seed, const int seedlen); /******************************************/ /* ** RC4 symmetric stream cypher */ /* ** Create a new RC4 context suitable for RC4 encryption/decryption. ** "key" raw key data ** "len" the number of bytes of key data */ extern RC4Context *RC4_CreateContext(const unsigned char *key, int len); /* ** Destroy an RC4 encryption/decryption context. ** "cx" the context ** "freeit" if PR_TRUE then free the object as well as its sub-objects */ extern void RC4_DestroyContext(RC4Context *cx, PRBool freeit); /* ** Perform RC4 encryption. ** "cx" the context ** "output" the output buffer to store the encrypted data. ** "outputLen" how much data is stored in "output". Set by the routine ** after some data is stored in output. ** "maxOutputLen" the maximum amount of data that can ever be ** stored in "output" ** "input" the input data ** "inputLen" the amount of input data */ extern SECStatus RC4_Encrypt(RC4Context *cx, unsigned char *output, unsigned int *outputLen, unsigned int maxOutputLen, const unsigned char *input, unsigned int inputLen); /* ** Perform RC4 decryption. ** "cx" the context ** "output" the output buffer to store the decrypted data. ** "outputLen" how much data is stored in "output". Set by the routine ** after some data is stored in output. ** "maxOutputLen" the maximum amount of data that can ever be ** stored in "output" ** "input" the input data ** "inputLen" the amount of input data */ extern SECStatus RC4_Decrypt(RC4Context *cx, unsigned char *output, unsigned int *outputLen, unsigned int maxOutputLen, const unsigned char *input, unsigned int inputLen); /******************************************/ /* ** RC2 symmetric block cypher */ /* ** Create a new RC2 context suitable for RC2 encryption/decryption. ** "key" raw key data ** "len" the number of bytes of key data ** "iv" is the CBC initialization vector (if mode is NSS_RC2_CBC) ** "mode" one of NSS_RC2 or NSS_RC2_CBC ** "effectiveKeyLen" is the effective key length (as specified in ** RFC 2268) in bytes (not bits). ** ** When mode is set to NSS_RC2_CBC the RC2 cipher is run in "cipher block ** chaining" mode. */ extern RC2Context *RC2_CreateContext(const unsigned char *key, unsigned int len, const unsigned char *iv, int mode, unsigned effectiveKeyLen); /* ** Destroy an RC2 encryption/decryption context. ** "cx" the context ** "freeit" if PR_TRUE then free the object as well as its sub-objects */ extern void RC2_DestroyContext(RC2Context *cx, PRBool freeit); /* ** Perform RC2 encryption. ** "cx" the context ** "output" the output buffer to store the encrypted data. ** "outputLen" how much data is stored in "output". Set by the routine ** after some data is stored in output. ** "maxOutputLen" the maximum amount of data that can ever be ** stored in "output" ** "input" the input data ** "inputLen" the amount of input data */ extern SECStatus RC2_Encrypt(RC2Context *cx, unsigned char *output, unsigned int *outputLen, unsigned int maxOutputLen, const unsigned char *input, unsigned int inputLen); /* ** Perform RC2 decryption. ** "cx" the context ** "output" the output buffer to store the decrypted data. ** "outputLen" how much data is stored in "output". Set by the routine ** after some data is stored in output. ** "maxOutputLen" the maximum amount of data that can ever be ** stored in "output" ** "input" the input data ** "inputLen" the amount of input data */ extern SECStatus RC2_Decrypt(RC2Context *cx, unsigned char *output, unsigned int *outputLen, unsigned int maxOutputLen, const unsigned char *input, unsigned int inputLen); /******************************************/ /* ** RC5 symmetric block cypher -- 64-bit block size */ /* ** Create a new RC5 context suitable for RC5 encryption/decryption. ** "key" raw key data ** "len" the number of bytes of key data ** "iv" is the CBC initialization vector (if mode is NSS_RC5_CBC) ** "mode" one of NSS_RC5 or NSS_RC5_CBC ** ** When mode is set to NSS_RC5_CBC the RC5 cipher is run in "cipher block ** chaining" mode. */ extern RC5Context *RC5_CreateContext(const SECItem *key, unsigned int rounds, unsigned int wordSize, const unsigned char *iv, int mode); /* ** Destroy an RC5 encryption/decryption context. ** "cx" the context ** "freeit" if PR_TRUE then free the object as well as its sub-objects */ extern void RC5_DestroyContext(RC5Context *cx, PRBool freeit); /* ** Perform RC5 encryption. ** "cx" the context ** "output" the output buffer to store the encrypted data. ** "outputLen" how much data is stored in "output". Set by the routine ** after some data is stored in output. ** "maxOutputLen" the maximum amount of data that can ever be ** stored in "output" ** "input" the input data ** "inputLen" the amount of input data */ extern SECStatus RC5_Encrypt(RC5Context *cx, unsigned char *output, unsigned int *outputLen, unsigned int maxOutputLen, const unsigned char *input, unsigned int inputLen); /* ** Perform RC5 decryption. ** "cx" the context ** "output" the output buffer to store the decrypted data. ** "outputLen" how much data is stored in "output". Set by the routine ** after some data is stored in output. ** "maxOutputLen" the maximum amount of data that can ever be ** stored in "output" ** "input" the input data ** "inputLen" the amount of input data */ extern SECStatus RC5_Decrypt(RC5Context *cx, unsigned char *output, unsigned int *outputLen, unsigned int maxOutputLen, const unsigned char *input, unsigned int inputLen); /******************************************/ /* ** DES symmetric block cypher */ /* ** Create a new DES context suitable for DES encryption/decryption. ** "key" raw key data ** "len" the number of bytes of key data ** "iv" is the CBC initialization vector (if mode is NSS_DES_CBC or ** mode is DES_EDE3_CBC) ** "mode" one of NSS_DES, NSS_DES_CBC, NSS_DES_EDE3 or NSS_DES_EDE3_CBC ** "encrypt" is PR_TRUE if the context will be used for encryption ** ** When mode is set to NSS_DES_CBC or NSS_DES_EDE3_CBC then the DES ** cipher is run in "cipher block chaining" mode. */ extern DESContext *DES_CreateContext(const unsigned char *key, const unsigned char *iv, int mode, PRBool encrypt); /* ** Destroy an DES encryption/decryption context. ** "cx" the context ** "freeit" if PR_TRUE then free the object as well as its sub-objects */ extern void DES_DestroyContext(DESContext *cx, PRBool freeit); /* ** Perform DES encryption. ** "cx" the context ** "output" the output buffer to store the encrypted data. ** "outputLen" how much data is stored in "output". Set by the routine ** after some data is stored in output. ** "maxOutputLen" the maximum amount of data that can ever be ** stored in "output" ** "input" the input data ** "inputLen" the amount of input data ** ** NOTE: the inputLen must be a multiple of DES_KEY_LENGTH */ extern SECStatus DES_Encrypt(DESContext *cx, unsigned char *output, unsigned int *outputLen, unsigned int maxOutputLen, const unsigned char *input, unsigned int inputLen); /* ** Perform DES decryption. ** "cx" the context ** "output" the output buffer to store the decrypted data. ** "outputLen" how much data is stored in "output". Set by the routine ** after some data is stored in output. ** "maxOutputLen" the maximum amount of data that can ever be ** stored in "output" ** "input" the input data ** "inputLen" the amount of input data ** ** NOTE: the inputLen must be a multiple of DES_KEY_LENGTH */ extern SECStatus DES_Decrypt(DESContext *cx, unsigned char *output, unsigned int *outputLen, unsigned int maxOutputLen, const unsigned char *input, unsigned int inputLen); /******************************************/ /* ** AES symmetric block cypher (Rijndael) */ /* ** Create a new AES context suitable for AES encryption/decryption. ** "key" raw key data ** "keylen" the number of bytes of key data (16, 24, or 32) ** "blocklen" is the blocksize to use (16, 24, or 32) ** XXX currently only blocksize==16 has been tested! */ extern AESContext * AES_CreateContext(const unsigned char *key, const unsigned char *iv, int mode, int encrypt, unsigned int keylen, unsigned int blocklen); /* ** Destroy a AES encryption/decryption context. ** "cx" the context ** "freeit" if PR_TRUE then free the object as well as its sub-objects */ extern void AES_DestroyContext(AESContext *cx, PRBool freeit); /* ** Perform AES encryption. ** "cx" the context ** "output" the output buffer to store the encrypted data. ** "outputLen" how much data is stored in "output". Set by the routine ** after some data is stored in output. ** "maxOutputLen" the maximum amount of data that can ever be ** stored in "output" ** "input" the input data ** "inputLen" the amount of input data */ extern SECStatus AES_Encrypt(AESContext *cx, unsigned char *output, unsigned int *outputLen, unsigned int maxOutputLen, const unsigned char *input, unsigned int inputLen); /* ** Perform AES decryption. ** "cx" the context ** "output" the output buffer to store the decrypted data. ** "outputLen" how much data is stored in "output". Set by the routine ** after some data is stored in output. ** "maxOutputLen" the maximum amount of data that can ever be ** stored in "output" ** "input" the input data ** "inputLen" the amount of input data */ extern SECStatus AES_Decrypt(AESContext *cx, unsigned char *output, unsigned int *outputLen, unsigned int maxOutputLen, const unsigned char *input, unsigned int inputLen); /******************************************/ /* ** AES key wrap algorithm, RFC 3394 */ /* ** Create a new AES context suitable for AES encryption/decryption. ** "key" raw key data ** "iv" The 8 byte "initial value" ** "encrypt", a boolean, true for key wrapping, false for unwrapping. ** "keylen" the number of bytes of key data (16, 24, or 32) */ extern AESKeyWrapContext * AESKeyWrap_CreateContext(const unsigned char *key, const unsigned char *iv, int encrypt, unsigned int keylen); /* ** Destroy a AES KeyWrap context. ** "cx" the context ** "freeit" if PR_TRUE then free the object as well as its sub-objects */ extern void AESKeyWrap_DestroyContext(AESKeyWrapContext *cx, PRBool freeit); /* ** Perform AES key wrap. ** "cx" the context ** "output" the output buffer to store the encrypted data. ** "outputLen" how much data is stored in "output". Set by the routine ** after some data is stored in output. ** "maxOutputLen" the maximum amount of data that can ever be ** stored in "output" ** "input" the input data ** "inputLen" the amount of input data */ extern SECStatus AESKeyWrap_Encrypt(AESKeyWrapContext *cx, unsigned char *output, unsigned int *outputLen, unsigned int maxOutputLen, const unsigned char *input, unsigned int inputLen); /* ** Perform AES key unwrap. ** "cx" the context ** "output" the output buffer to store the decrypted data. ** "outputLen" how much data is stored in "output". Set by the routine ** after some data is stored in output. ** "maxOutputLen" the maximum amount of data that can ever be ** stored in "output" ** "input" the input data ** "inputLen" the amount of input data */ extern SECStatus AESKeyWrap_Decrypt(AESKeyWrapContext *cx, unsigned char *output, unsigned int *outputLen, unsigned int maxOutputLen, const unsigned char *input, unsigned int inputLen); /******************************************/ /* ** MD5 secure hash function */ /* ** Hash a null terminated string "src" into "dest" using MD5 */ extern SECStatus MD5_Hash(unsigned char *dest, const char *src); /* ** Hash a non-null terminated string "src" into "dest" using MD5 */ extern SECStatus MD5_HashBuf(unsigned char *dest, const unsigned char *src, uint32 src_length); /* ** Create a new MD5 context */ extern MD5Context *MD5_NewContext(void); /* ** Destroy an MD5 secure hash context. ** "cx" the context ** "freeit" if PR_TRUE then free the object as well as its sub-objects */ extern void MD5_DestroyContext(MD5Context *cx, PRBool freeit); /* ** Reset an MD5 context, preparing it for a fresh round of hashing */ extern void MD5_Begin(MD5Context *cx); /* ** Update the MD5 hash function with more data. ** "cx" the context ** "input" the data to hash ** "inputLen" the amount of data to hash */ extern void MD5_Update(MD5Context *cx, const unsigned char *input, unsigned int inputLen); /* ** Finish the MD5 hash function. Produce the digested results in "digest" ** "cx" the context ** "digest" where the 16 bytes of digest data are stored ** "digestLen" where the digest length (16) is stored ** "maxDigestLen" the maximum amount of data that can ever be ** stored in "digest" */ extern void MD5_End(MD5Context *cx, unsigned char *digest, unsigned int *digestLen, unsigned int maxDigestLen); /* * Return the the size of a buffer needed to flatten the MD5 Context into * "cx" the context * returns size; */ extern unsigned int MD5_FlattenSize(MD5Context *cx); /* * Flatten the MD5 Context into a buffer: * "cx" the context * "space" the buffer to flatten to * returns status; */ extern SECStatus MD5_Flatten(MD5Context *cx,unsigned char *space); /* * Resurrect a flattened context into a MD5 Context * "space" the buffer of the flattend buffer * "arg" ptr to void used by cryptographic resurrect * returns resurected context; */ extern MD5Context * MD5_Resurrect(unsigned char *space, void *arg); /* ** trace the intermediate state info of the MD5 hash. */ extern void MD5_TraceState(MD5Context *cx); /******************************************/ /* ** MD2 secure hash function */ /* ** Hash a null terminated string "src" into "dest" using MD2 */ extern SECStatus MD2_Hash(unsigned char *dest, const char *src); /* ** Create a new MD2 context */ extern MD2Context *MD2_NewContext(void); /* ** Destroy an MD2 secure hash context. ** "cx" the context ** "freeit" if PR_TRUE then free the object as well as its sub-objects */ extern void MD2_DestroyContext(MD2Context *cx, PRBool freeit); /* ** Reset an MD2 context, preparing it for a fresh round of hashing */ extern void MD2_Begin(MD2Context *cx); /* ** Update the MD2 hash function with more data. ** "cx" the context ** "input" the data to hash ** "inputLen" the amount of data to hash */ extern void MD2_Update(MD2Context *cx, const unsigned char *input, unsigned int inputLen); /* ** Finish the MD2 hash function. Produce the digested results in "digest" ** "cx" the context ** "digest" where the 16 bytes of digest data are stored ** "digestLen" where the digest length (16) is stored ** "maxDigestLen" the maximum amount of data that can ever be ** stored in "digest" */ extern void MD2_End(MD2Context *cx, unsigned char *digest, unsigned int *digestLen, unsigned int maxDigestLen); /* * Return the the size of a buffer needed to flatten the MD2 Context into * "cx" the context * returns size; */ extern unsigned int MD2_FlattenSize(MD2Context *cx); /* * Flatten the MD2 Context into a buffer: * "cx" the context * "space" the buffer to flatten to * returns status; */ extern SECStatus MD2_Flatten(MD2Context *cx,unsigned char *space); /* * Resurrect a flattened context into a MD2 Context * "space" the buffer of the flattend buffer * "arg" ptr to void used by cryptographic resurrect * returns resurected context; */ extern MD2Context * MD2_Resurrect(unsigned char *space, void *arg); /******************************************/ /* ** SHA-1 secure hash function */ /* ** Hash a null terminated string "src" into "dest" using SHA-1 */ extern SECStatus SHA1_Hash(unsigned char *dest, const char *src); /* ** Hash a non-null terminated string "src" into "dest" using SHA-1 */ extern SECStatus SHA1_HashBuf(unsigned char *dest, const unsigned char *src, uint32 src_length); /* ** Create a new SHA-1 context */ extern SHA1Context *SHA1_NewContext(void); /* ** Destroy a SHA-1 secure hash context. ** "cx" the context ** "freeit" if PR_TRUE then free the object as well as its sub-objects */ extern void SHA1_DestroyContext(SHA1Context *cx, PRBool freeit); /* ** Reset a SHA-1 context, preparing it for a fresh round of hashing */ extern void SHA1_Begin(SHA1Context *cx); /* ** Update the SHA-1 hash function with more data. ** "cx" the context ** "input" the data to hash ** "inputLen" the amount of data to hash */ extern void SHA1_Update(SHA1Context *cx, const unsigned char *input, unsigned int inputLen); /* ** Finish the SHA-1 hash function. Produce the digested results in "digest" ** "cx" the context ** "digest" where the 16 bytes of digest data are stored ** "digestLen" where the digest length (20) is stored ** "maxDigestLen" the maximum amount of data that can ever be ** stored in "digest" */ extern void SHA1_End(SHA1Context *cx, unsigned char *digest, unsigned int *digestLen, unsigned int maxDigestLen); /* ** trace the intermediate state info of the SHA1 hash. */ extern void SHA1_TraceState(SHA1Context *cx); /* * Return the the size of a buffer needed to flatten the SHA-1 Context into * "cx" the context * returns size; */ extern unsigned int SHA1_FlattenSize(SHA1Context *cx); /* * Flatten the SHA-1 Context into a buffer: * "cx" the context * "space" the buffer to flatten to * returns status; */ extern SECStatus SHA1_Flatten(SHA1Context *cx,unsigned char *space); /* * Resurrect a flattened context into a SHA-1 Context * "space" the buffer of the flattend buffer * "arg" ptr to void used by cryptographic resurrect * returns resurected context; */ extern SHA1Context * SHA1_Resurrect(unsigned char *space, void *arg); /******************************************/ extern SHA256Context *SHA256_NewContext(void); extern void SHA256_DestroyContext(SHA256Context *cx, PRBool freeit); extern void SHA256_Begin(SHA256Context *cx); extern void SHA256_Update(SHA256Context *cx, const unsigned char *input, unsigned int inputLen); extern void SHA256_End(SHA256Context *cx, unsigned char *digest, unsigned int *digestLen, unsigned int maxDigestLen); extern SECStatus SHA256_HashBuf(unsigned char *dest, const unsigned char *src, uint32 src_length); extern SECStatus SHA256_Hash(unsigned char *dest, const char *src); extern void SHA256_TraceState(SHA256Context *cx); extern unsigned int SHA256_FlattenSize(SHA256Context *cx); extern SECStatus SHA256_Flatten(SHA256Context *cx,unsigned char *space); extern SHA256Context * SHA256_Resurrect(unsigned char *space, void *arg); /******************************************/ extern SHA512Context *SHA512_NewContext(void); extern void SHA512_DestroyContext(SHA512Context *cx, PRBool freeit); extern void SHA512_Begin(SHA512Context *cx); extern void SHA512_Update(SHA512Context *cx, const unsigned char *input, unsigned int inputLen); extern void SHA512_End(SHA512Context *cx, unsigned char *digest, unsigned int *digestLen, unsigned int maxDigestLen); extern SECStatus SHA512_HashBuf(unsigned char *dest, const unsigned char *src, uint32 src_length); extern SECStatus SHA512_Hash(unsigned char *dest, const char *src); extern void SHA512_TraceState(SHA512Context *cx); extern unsigned int SHA512_FlattenSize(SHA512Context *cx); extern SECStatus SHA512_Flatten(SHA512Context *cx,unsigned char *space); extern SHA512Context * SHA512_Resurrect(unsigned char *space, void *arg); /******************************************/ extern SHA384Context *SHA384_NewContext(void); extern void SHA384_DestroyContext(SHA384Context *cx, PRBool freeit); extern void SHA384_Begin(SHA384Context *cx); extern void SHA384_Update(SHA384Context *cx, const unsigned char *input, unsigned int inputLen); extern void SHA384_End(SHA384Context *cx, unsigned char *digest, unsigned int *digestLen, unsigned int maxDigestLen); extern SECStatus SHA384_HashBuf(unsigned char *dest, const unsigned char *src, uint32 src_length); extern SECStatus SHA384_Hash(unsigned char *dest, const char *src); extern void SHA384_TraceState(SHA384Context *cx); extern unsigned int SHA384_FlattenSize(SHA384Context *cx); extern SECStatus SHA384_Flatten(SHA384Context *cx,unsigned char *space); extern SHA384Context * SHA384_Resurrect(unsigned char *space, void *arg); /******************************************/ /* ** Pseudo Random Number Generation. FIPS compliance desirable. */ /* ** Initialize the global RNG context and give it some seed input taken ** from the system. This function is thread-safe and will only allow ** the global context to be initialized once. The seed input is likely ** small, so it is imperative that RNG_RandomUpdate() be called with ** additional seed data before the generator is used. A good way to ** provide the generator with additional entropy is to call ** RNG_SystemInfoForRNG(). Note that NSS_Init() does exactly that. */ extern SECStatus RNG_RNGInit(void); /* ** Update the global random number generator with more seeding ** material */ extern SECStatus RNG_RandomUpdate(const void *data, size_t bytes); /* ** Generate some random bytes, using the global random number generator ** object. */ extern SECStatus RNG_GenerateGlobalRandomBytes(void *dest, size_t len); /* Destroy the global RNG context. After a call to RNG_RNGShutdown() ** a call to RNG_RNGInit() is required in order to use the generator again, ** along with seed data (see the comment above RNG_RNGInit()). */ extern void RNG_RNGShutdown(void); /* Generate PQGParams and PQGVerify structs. * Length of seed and length of h both equal length of P. * All lengths are specified by "j", according to the table above. */ extern SECStatus PQG_ParamGen(unsigned int j, /* input : determines length of P. */ PQGParams **pParams, /* output: P Q and G returned here */ PQGVerify **pVfy); /* output: counter and seed. */ /* Generate PQGParams and PQGVerify structs. * Length of P specified by j. Length of h will match length of P. * Length of SEED in bytes specified in seedBytes. * seedBbytes must be in the range [20..255] or an error will result. */ extern SECStatus PQG_ParamGenSeedLen( unsigned int j, /* input : determines length of P. */ unsigned int seedBytes, /* input : length of seed in bytes.*/ PQGParams **pParams, /* output: P Q and G returned here */ PQGVerify **pVfy); /* output: counter and seed. */ /* Test PQGParams for validity as DSS PQG values. * If vfy is non-NULL, test PQGParams to make sure they were generated * using the specified seed, counter, and h values. * * Return value indicates whether Verification operation ran succesfully * to completion, but does not indicate if PQGParams are valid or not. * If return value is SECSuccess, then *pResult has these meanings: * SECSuccess: PQGParams are valid. * SECFailure: PQGParams are invalid. * * Verify the following 12 facts about PQG counter SEED g and h * 1. Q is 160 bits long. * 2. P is one of the 9 valid lengths. * 3. G < P * 4. P % Q == 1 * 5. Q is prime * 6. P is prime * Steps 7-12 are done only if the optional PQGVerify is supplied. * 7. counter < 4096 * 8. g >= 160 and g < 2048 (g is length of seed in bits) * 9. Q generated from SEED matches Q in PQGParams. * 10. P generated from (L, counter, g, SEED, Q) matches P in PQGParams. * 11. 1 < h < P-1 * 12. G generated from h matches G in PQGParams. */ extern SECStatus PQG_VerifyParams(const PQGParams *params, const PQGVerify *vfy, SECStatus *result); /* * clean-up any global tables freebl may have allocated after it starts up. * This function is not thread safe and should be called only after the * library has been quiessed. */ extern void BL_Cleanup(void); /************************************************************************** * Verify a given Shared library signature * **************************************************************************/ PRBool BLAPI_SHVerify(const char *name, PRFuncPtr addr); /************************************************************************** * Verify Are Own Shared library signature * **************************************************************************/ PRBool BLAPI_VerifySelf(const char *name); SEC_END_PROTOS #endif /* _BLAPI_H_ */